DE3736374C2 - - Google Patents

Description

The invention relates to a method for transferring against a given television standard Standard image signal according to the preamble of the claim 1, in which the standard image signal from the multiple image supplied image signals is composed.

A method of this type is described in DE 34 01 811 A1 wrote. In this known method, several from different image sources in the form of Video cameras originating in such a way ge common output signal that this off a signal corresponding to a certain television standard Represents standard image signal. With this measure, he will is enough that the said output signal z. B. one zigen, the respective television standard channel broadcast or in a single channel of a video Recording device can be saved, although it is the Contains information from several image sources. So that's him generated output signal to conventional image signals of each certain TV standards fully compliant and required only a suitable device for playback Extraction of the image signals of the desired image source len.  

In the known method, the composition of the Output signal in such a way that each of the image signals Image source only a certain one, for example some Containing rows and / or columns of the total image area Drawing file is taken out, taking care that the total number of rows and columns picked out the total number of rows and columns of the Picture format does not exceed the selected TV standard. Consequently, by appropriate displacement or placement an overall image of the individual partial images is generated, the This amount of information corresponds to that of a standard picture.

A disadvantage of the known method is that playback of an extracted image source only the corresponding amount of information to the selected drawing file is common. This method is therefore only applicable bar if in certain situations, such as B. in the simul tan transmission of video conferences to certain Areas of the video image, such as the background the conference participant, can be waived without further notice can. Furthermore, the number of images that can be transmitted simultaneously signals relatively limited to a few, because an excessive reduction in the size of the selected parts rich does not seem reasonable.

Subject of the reference "IEEE Transactions on Consu mer Electronics ", vol. CE-31, No.2, pages 82 to 87 a method for the transmission of three-dimensional television picture the one using two stereoscopically arranged TV cameras are recorded, with each being straight Fields of the transmitted image signal the image information For example, the right camera included, whereas the odd fields the image information of the left camera contain. To get a stereoscopic impression from the transmitted this way and by means of a television set To receive the reproduced television picture, a respective  Viewers wear special glasses for every eye a liquid crystal shutter which can be mutually controlled so that each eye only the image information generated by the associated television camera tion is accessible.

Finally, from DE-OS 29 20 303 is a device for the transmission of several, of different surveillance video signals from a camera number of transmission channels known, for the Detection of transmission errors and / or for identification a coding device for each surveillance camera tion is provided in the image-free lines a suitable one between two successive images Inserts code signal. In this way it is achieved that the Identification without additional provision of an aid carrier frequency is possible.

The invention has for its object a method according to the preamble of claim 1 to form that without significant loss of relevant picture information from the image signals of many image sources composing standard image signal is transferable.

According to the invention, this object is characterized by the the part of claim 1 specified process step solved.

According to the invention it is achieved that all in the standard Image signal contained image signals of different image sources do not lose essential image information. Single Lich the dynamic resolution, d. H. the speed of Movements are reduced by the number of image sources set; however, this is the main one for the majority Lichen application areas of the invention, such as in particular surveillance technology, no significant restriction  Thus, the method according to the invention is itself at a number of about 50 image sources in practice well usable.

Advantageous developments of the invention are the subject of subclaims.

The invention is described below based on the description of Embodiments with reference to the drawing explained in more detail. It shows

Fig. 1 is a schematic sketch of the principle explanation of the inventive method;

Fig. 2 is a block diagram of an embodiment of a first signal generating device which operates according to the inventive method;

Fig. 3 is a block diagram of a second embodiment of such a signal generating apparatus, by means of which image signals of asynchronous image sources can be processed; and

Fig. 4 is a block diagram of an embodiment of an image signal extraction device.

With reference to FIG. 1, the first of the invention is to underlying principle will be explained. Referring to FIG. 1 A is provided to X at game as image sources in which it is z. B. can be cameras and each deliver an image signal corresponding to a captured image, which is indicated schematically with an arrow. If the image signal is a standard television signal corresponding to a specific television standard or a specific television standard, this image signal contains, as image information, fields which are generated 50 or 60 times per second depending on the selected television standard and alternately one line -Offset, so that two successive fields each result in a frame. The fields mentioned are indicated in FIG. 1 by a square which has the reference symbol of the assigned image source.

From Fig. 1 it can be seen that according to the invention each field of a respective image signal is only offered at certain intervals as an output signal, namely in the case shown in Fig. 1 at an interval which is predetermined by the number of image sources A to X. It follows that the image signal of a respective image source, z. B. the image source A, not in the number corresponding to the selected television standard (ie 50 or 60 times per second), but only in a number divided by the number of image sources per second is available. This is achieved with a corresponding reduction in the dynamic resolution of the image signals of the individual image sources that, in spite of the image signals originating from several image sources, a standard image signal is again available, the transmission of which, for. B. with means of a standard television transmission device, that is to say via a conventional transmission channel. Likewise, the signal generated by the method according to the invention can be recorded by means of a conventional standard video recording device for documentation purposes.

As will be explained in more detail later with reference to FIG. 4, the image signal of a particular image source is extracted from the standard image signal generated in this way, preferably in that intermediate storage of the last image in each case occurs until the arrival of the next field of the relevant image source Field of this image source is carried out so that this buffered field can be displayed on a monitor, for example, by repeatedly reading out the buffer until the next field is present (for example after fields B to X). In this extraction is also by means of a source identifier also explained later, which is inserted according to FIG. 1 preferably after the occurrence of vertical pulses VI in the standard image signal, also ensures that from the transmitted plurality of image information or image signals from different image sources in each case only the correct, ie respectively desired, image is processed.

A signal generation device is described below with reference to FIG. 2, by means of which, according to the method explained above, several image sources can be output sequentially at a single output OUT in the form of a standard image signal, in the case of FIG. 2 it being assumed that image signals to be combined A to X of different image sources are synchronized with each other. According to FIG. 2, the image signals A to X are first supplied to their own clamping circuit (KA to KX), which ensure that the synchronous blanking level of all image signals A to X is kept at the same voltage level regardless of their respective image content. The output signals of the clamping circuits KA to KX are fed to a multiplexer M with a number of inputs corresponding to the number of image sources, which receives a changeover signal USS from a vertical counter VZ and one of the clamped image signals A to X in the clock cycle predetermined by this changeover signal USS leads to an output stage AS in a cyclic sequence.

The vertical information generated by the vertical counter VZ is simultaneously fed to a source encoder or encoder QC, which supplies the output stage AS with a source coding or identifier such that the output stage AS receives the image signal just switched through by the multiplexer M (image signal in FIG. 2

• A) during the vertical blanking interval this image si gnal assigned source identifier admixed.

Fig. 3 shows a signal generating device which, in contrast to the device shown in Fig. 2, he allows the sequential composition of the image signals even those image sources that are not synchronized with each other, that is, asynchronous. As can be seen directly from FIG. 3, the image signals to be combined are divided into three groups I, II and III, image signals A to X being transmitted within each group in the exemplary embodiment; Overall, who the 3 * (A to X) image signals transmitted in this embodiment, which are designated with IA to IX, IIA to IIX and IIIA to IIIX.

As in the case of the signal generating device of FIG. 2, the voltage of the supplied image signals is initially clamped, but the corresponding clamping circuits are not shown. The clamped image signals of each group I to III are present at the inputs of a respective multiplexer MI to MIII, which is assigned to the relevant signal group. The output of each of the multiplexers MI to MIII is connected to the input of a respectively assigned, synchronizable field memory SI or SII or SIII, which are preferably electronic memories. Referring to FIG. 3, the outputs of the three field memory SI are each an output multiplexer connected to AM SIII with one of three inputs, whose output is in turn connected to an output stage AS. For cyclic control of the three multiplexers MI to MIII, the three field memories SI to SIII and the output multiplexer AM, a switchover logic processor ULP is provided, which, like the field memory and the output stage AS, is provided by a clock generator TG with central synchronism impulses is supplied.

The switching logic processor ULP wins from the vertical im pulse the required switching information for the three Multiplexer MI to MIII as well as for the output multiplexer AT THE. He also ensures that immediately after reading one of the field memories SI to SIII this through Fort switch the assigned multiplexer MI, MII or MIII new is loaded. Meanwhile, the output multiplexer AM also switched to the rhythm of the vertical pulses. Accordingly, the respective image signals with the field Frequency read into the field memories SI to SIII; the reading of these three memories and thus the transfer of the now synchronized image signals to the output stage AS also takes place at the field frequency. In execution The fields of the image signals are therefore an example the connected image sources in the order IA, IIA, IIIA, IB, IIB etc. output at an output OUT.

The switching logic processor ULP also controls a source encoder QC, which, as in the case of FIG. 2, supplies the output stage AS with a source identifier such that the output stage AS outputs the image signal just switched through by the multiplexer M (in FIG Field memory SI ge stored) during the vertical blanking interval one source identifier assigned to the relevant image source.

An extraction device is described below with reference to FIG. 4, which is suitable for extracting one of the plurality of image signals that were inserted into the standard image signal by means of the signal generating device shown in FIG. 2 or 3. The standard image signal coming from a transmission device or also from a video recording device is first fed to an input isolation amplifier TV, which generates a low-impedance output signal which is fed to a field memory S. The output signal of the input isolation amplifier TV is also present at the respective input of a synchronous pulse isolation stage SA and a source decoder QD.

The synchronizing pulse separation stage SA provides the field picture cher S synchronous pulses are available in permanent succession, which synchronize the reading of the field memory S; this makes it possible to output the field memory S to be viewed on a screen or monitor M. ten.

In addition, the synchronizing pulse separation stage sets SA Measurement window available during which the source decoder QD the code or identifier of the image just transferred source recorded. By means of a keyboard T an operator can each person choose which of the several received Image sources should be displayed on monitor M. The sources For this purpose, decoder QD compares that of the Keyboard T generated code with the source received in each case lencode and only then generates an enable signal FS for the Field memory S if both codes match. Episode Lich the field memory S is only when it occurs a release signal, d. H. only when one is concerned Field of a selected image source with the ge just received field described.

By intervening in the reading process of the Halbbildspei chers S, it is still possible to display still images or make size or scale changes to the image information. In addition, it is possible, by connecting a corresponding number of the device shown in FIG. 4 in parallel, to display several or all of the transmitted image signals simultaneously using a corresponding number of monitors.

Claims (13)

1. A method for transmitting a standard television signal standard television signal standard, which is composed of the image signals supplied by several image sources, characterized in that

• A) that the image signal corresponding to a complete field of one of the several image sources is transmitted as the standard image signal,
• B) that, following this field, the fields of all other image sources are transmitted in sequential sequence,
• C) that the sequential transmission of the fields from all image sources is repeated cyclically,
• D) that a source identifier enabling the identification of the assigned image source is added to each transmitted field, and
• E) that upon receipt for extracting the image signal of a specific image source, the source identifier assigned to this is detected in the standard image signal.

2. The method according to claim 1 for the composition of a standard image signal in which the individual image sources are not synchronized, characterized in that

• A) that the multiple image sources are divided into three groups,
• B) that in each group the field of one of the image sources is stored in a synchronizable memory assigned to this group,
• C) that the fields of all other image sources of the relevant group are stored in sequential order and in cyclic repetition, and
• D) that one of the three memories is read out in cyclical sequence in the rhythm predetermined by the field frequency and its memory signal is transmitted as a standard image signal.

3. The method according to claim 1 or 2, characterized that the source identifier in the vertical blanking interval between between two consecutive fields. 4. The method according to any one of claims 1 to 3, characterized in that the standard image signal provided by means of of a video recording device becomes. 5. The method according to any one of claims 1 to 4, characterized in

• (A) that the field present when the source identifier is acquired is stored in a buffer until the relevant source identifier is acquired again, and
• (B) that the buffer is read out in the meantime and its storage signal is provided as an image signal of the image source to be extracted.

6. The method according to claim 5, characterized in that for extracting the image signals of several or all in the Image sources containing the standard image signal follow the procedure Claim 5 carried out in parallel in a corresponding number becomes.   7. The method according to claim 5 or 6, characterized in that that an extracted image signal at one of the relevant Image source associated screen is displayed. 8. Device for generating a standard image signal composed according to claim 1, in which synchronized image sources deliver the image signals, characterized by

• (A) a multiplexer (M) with a number of inputs corresponding to the number of image signals (AX) to be combined, at each of which the image signal (AX) of one of the image sources is present,
• (B) a source encoder (QC) which generates a source identifier assigned to the image signal (A) which has just been switched through by the multiplexer (M),
• (C) a vertical counter (VZ) which, in response to a vertical pulse of one of the several image signals (AX), outputs a signal (USS) which switches the multiplexer (M) and a signal which causes the source encoder to generate a source identifier, and by
• (D) an output stage (AS) which adds to the image signal (A) which has just been switched through by the multiplexer (M), its source identifier generated by the source encoder (QC).

9. Device for generating a standard image signal composed according to claim 2, in which unsynchronized image sources deliver the image signals, characterized by

• (A) three multiplexers (MI-MIII) with a number of inputs corresponding to the number of image signals present in each group (I-III), at each of which the image signal (AX) of one of the image sources of the respective group is present,
• (B) three still image memories (SI-SIII), each of which stores the image signal switched through by an assigned multiplexer (MI-MIII) in the context of a field,
• C) an output multiplexer (AM) which has three inputs, at each of which the output signal of an assigned field memory (SI-SIII) is present,
• (D) a switching logic processor (ULP) which switches the three multiplexers (MI-MIII) and the output multiplexer (AM) in the field frequency,
• (E) a source encoder (QC) which generates a source identifier assigned to the image signal (IA) which has just been switched through by the output multiplexer (AM),
• (F) an output stage (AS) which adds to the image signal (A) which has just been switched through by the output multiplexer (AM), its source identifier generated by the source encoder (QC), and by
• (G) a clock generator (TG) which supplies the switching logic processor (ULP), the three field memories (SI-SIII) and the output stage with synchronization pulses.

10. The device according to claim 8 or 9, characterized in that that before the respective inputs of the multiplexer (s) (M or MI-MIII) one clamping step each (KA-KX) is switched, which is an adjustment of the voltage level of all Carry out image signals. 11. An apparatus for performing the method according to claim 5 for extracting image signals, characterized by

• (A) a source decoder (QD), which detects the source identifiers inserted into the standard image signal and generates an enable signal if the respectively detected source identifier matches the identifier of a respective image signal to be extracted, and by
• (B) a field memory (S) which, upon receipt of the release signal, begins to store a field contained in the standard image signal.

12. The apparatus according to claim 11, characterized in that the output signal of the field memory (S) a screen (M) can be fed. 13. The apparatus according to claim 11 or 12, characterized in that that the image signal to be extracted in each case by means of a keyboard (T) can be selected manually.